Effects of Plastic Mulch, Row Cover & Cultivar Selection on Growth of Tomatoes in High Tunnels; Gardening Guidebook for Boone County, Missouri

8/9/2019 Effects of Plastic Mulch, Row Cover & Cultivar Selection on Growth of Tomatoes in High Tunnels; Gardening Guideb…

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EFFECTS OF PLASTIC MULCH, ROW COVER, AND CULTIVAR SELECTION ON

GROWTH OF TOMATOES ( Lycopersicon esculentum Mill.) IN HIGH TUNNELS

____________________

A Thesis Presented to

the Faculty of the Graduate School

University of Missouri-Columbia

____________________

In Partial Fulfillment

of the Requirements for the Degree

Master of Science

____________________

By

ROBERT ANDREW READ

Dr. David Trinklein, Thesis Supervisor

December, 2007


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The undersigned, appointed by the Dean of the Graduate School, have examined

the thesis entitled

EFFECTS OF PLASTIC MULCH, ROW COVER, AND CULTIVAR SELECTION ONGROWTH OF TOMATOES ( Lycopersicon esculentum Mill.) IN HIGH TUNNELS

Presented by Robert Andrew Read

A candidate for the degree of Master of Science

Andy hereby certify that in their opinion it is worthy of acceptance.

________________________________________

Professor David Trinklein

________________________________________

Professor Christopher Starbuck

________________________________________

Professor Mark Ellersieck


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ACKNOWLEDGEMENTS

I would like to thank Dr. David Trinklein for his wonderful insight and hard work

to help me complete this thesis. Dr. Trinklein took time from his busy schedule to advise

me and to put together committees and meetings on timetables that sometimes seemed

impossible. Thanks for going out of your way when you didn’t have to.

I would also like to thank Dr. Starbuck. He always took time to answer questions

I had and also to show me other resources that related to problems I was encountering.

Dr. Starbucks kindness and sincerity gave me hope on several occasions when I really

needed it.

I give special thanks to Dr. Mark Ellersieck. Dr. Ellersieck is a valuable resource

to the University of Missouri. He is somehow able to infuse humor into a subject that can

at times be anything but funny. Dr. Ellersieck has a great mind for looking at things

analytically and I only hope to be able to think more like him as my career progresses.

Last but certainly not least I would like to thank Tim Reinbott. Tim made

materials and equipment available to me during my research that was essential to its

completion. Tim is a very knowledgeable grower and his general concern for the success

of others helped me complete my research.

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TABLE OF CONTENTS

ACKNOWLEDGEMENTS…………………………………………………………..ii

LIST OF TABLES…………………………………………………………………….v

ABSTRACT…………………………………………………………………………..vi

Chapter

I. INTRODUCTION…………………………………………………………… 1

II. LITERATURE REVIEW……………………………………………………. 2

Plastic mulch…………………………………………………………. 3

Floating Row Covers………………………………………………… 6

Drip Irrigation…………………………………………………………7

High Tunnels…………………………………………………………. 8

Economics of High Tunnel Production……………………………….10

Cultivar Selection……………………………………………………...11

III. EFFECT OF MULCH AND ROW COVERS ON YIELD OF TOMATOES IN HIGH

TUNNELS…………………………………………………………………… 12

1) Abstract………………………………………………………….... 12

2) Introduction………………………………………………………. 12

3) Materials and Methods…………………………………………… 16

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4) Results……………….…………………………………………… 19

5) Discussion...………………………………………………………. 22

IV. EVALUATION OF YIELD POTENTIAL IN HIGH TUNNELS FOR EIGHT TOMATO

CULTIVARS………………………………………………………………… 24

1) Abstract…………………………………………………………… 24

2) Introduction………………………………………………………. 25

3) Materials and Methods…………………………………………… 27

4) Results……………….…………………………………………… 29

5) Discussion...………………………………………………………. 32

V. SUMMARY AND CONCLUSIONS………………………………………...34

VI. LITERATURE CITED……………………………………………………….36

APPENDIX

I: Soil Test Results…………………………………………………………... 41

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LIST OF TABLES

Table Page

1. Mulch and Row Cover Treatments………………………………………… 17

2. Total Yield of Mulch Treatments………………………………………….. 20

3. Early Yield of Mulch Treatments (Before July 4)…………………………. 21

4. Necrotic Tissue Due to Cold Damage……………………………………... 21

5. Early Yield for Cultivar Trial (Before July 4)……………………………... 30

6. Percent Culls Due to Applicable Reason…………………………………... 31

7. Yield Data for Cultivar Trial………………………………………………. 32

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ABSTRACT

Tomato plants ( Lycopersicon esculentum Mill.) were grown to: 1) evaluate their early

season yield characteristics when grown using different mulch types with and without row cover;

and 2) evaluate yield potential among different cultivars when grown in high tunnels. Row

covers did not significantly increase total, or US number 1 yield of high tunnel tomatoes. Clear

plastic mulch significantly increases early yield of grade 1 fruit over all other treatments. Total

early yields from BHN 543, and Merced were significantly greater than all other cultivars. Due

to early fruit ripening characteristics, BHN 543 could fit into a double cropping system for

growers wanting to replant their high tunnels with a fall crop. Full season yield of grade 1 and 2

fruit combined was significantly greater for Merced than any other cultivar. The heirloom tomato

cultivar Brandywine produced significantly less early total and grade 1 fruit per plant than

Merced or BHN 543.

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Chapter 1

Introduction

Enhanced early season production and improved quality are important factors for

warm season vegetable crop growers. The intent is to grow crops where otherwise they

could not survive by modifying the growing environment to prolong the harvest period,

often with earlier maturity, greater yields and improved quality, making commodities

available when there is no outdoor production (Wittwer and Castilla, 1995). Climate is

the predominant factor that determines food and fiber production (Dalrymple, 1973).

Therefore, growers who have the ability to modify their climate have a competitive

advantage over growers in the same region that do not have the ability to manipulate their

climate. Manipulation of the growing season can be achieved through a variety of

cultural practices. Structures such as greenhouses are an effective means in lengthening

the growing season but require initial investments of $5.86/ft², compared to $1.50 -

$2.00/ft² for high tunnels (MSU Greenhouse Extension Guide). Operational costs

required to run greenhouses have also proven to be greater than potential returns for

many warm season vegetables (Atherton and Rudich, 1986). Other, less expensive

season extension strategies that have been proven effective include: row covers

(Motsenbocker, 1989), plastic mulch (Lamont, 1993), and high tunnels (Coleman, 1989).

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Little is known however about the effects of row cover and different colored plastic

mulches on high tunnel grown tomatoes in the Central Midwest. The objective of the

first study was to compare the effects on tomatoes of black plastic mulch, clear plastic

mulch, and no mulch, each with and without row cover when used in high tunnels. The

effect of environmental factors within high tunnels on yield of popular field grown

tomato cultivars is also a topic about which little is known. The objective of the second

study was to determine yield characteristics throughout the growing season for several

popular tomato cultivars commonly grown in Missouri.

Chapter 2

Review of Literature

The development of the polyethylene polymer in the 1930’s, and its release onto

the market in the early 1950’s in the form of plastic films, allowed for profitable

production of certain vegetables within plastic covered structures (Lamont, 1996).

During this time period, unheated plastic covered structures became popular for vegetable

production in Asian and Mediterranean countries. Glasshouses in Northern Europe that

were used for vegetable production prior to the 1950’s underwent a shift to production of

high value ornamental crops such as flowers and potted plants (Wittwer and Castilla,

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1995). During this time period E.M. Emmert began research growing crops in plastic

covered structures with the use of mulch and row covers at the University of Kentucky

(Emmert, 1954, 1955, 1956, 1957). These developments during the early 1950’s gave

rise to a new system of vegetable production known worldwide as plasticulture.

Important inputs of a plasticulture system include plastic and non-plastic

components such as: plastic mulch, plastic film, row cover, drip irrigation, fertigation and

windbreaks (Lamont, 1996). Sound crop rotations, crop scouting, and aggressive

marketing of crops should be practiced to maximize productivity of a plasticulture

system.

To understand a plasticulture system it is important to understand its individual

components.

Plastic Mulch

E.M. Emmert (1956) found black polyethylene mulch to be the cheapest and most

efficient method used to mulch vegetables. Benefits of plastic mulch include: increased

and earlier harvests, higher quality produce, better weed control and insect management,

and more efficient use of irrigation water and fertigation nutrients (Lamont, 1993).

Major advances in plastics have taken place since E.M. Emmerts’ work in the early 50’s.

Today growers can choose from a variety of mulches, each of which has its own specific

application.

To extend the growing season of a certain crop, it is necessary to grow the crop in

sub-optimal conditions such as cold weather. Cool soil temperatures can have a number

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of adverse effects on plant root growth such as: slower cell division and cell maturation

rates, reduced water uptake, and reduced nutrient uptake (Nielsen, 1974). Black and

clear mulches have shown the greatest soil warming potential among the various mulch

colors (Ham et al., 1993). However, black and clear mulches heat the soil in different

ways, and how the mulch is applied to the soil is directly related to its effectiveness.

Black mulch reflects less short-wave radiation (10%) and absorbs more radiation

(90%) than any other colored mulch (Teasdale, 1995). Dark colored mulches (black or

red) typically have higher surface temperatures than clear or white mulch (Decoteau et

al., 1989). The heat absorbed by dark -colored mulches is conducted to the soil surface,

which raises the soil temperature (Tarara, 2000). Therefore, it is very important to apply

dark plastics tightly over the bed to maintain good soil- to -mulch contact. An air gap

between the mulch and the soil creates a greater distance for the heat to travel before

entering the soil and, consequently, much of the heat created at the mulch surface is lost

to the atmosphere (Tarara, 2000).

Clear mulch absorbs only 5% of short-wave radiation, reflects 11%, but transmits

84% of it (Tarara, 2000). Clear mulch surface temperatures do not reach the levels found

on black plastic due to their low absorption rates of short-wave radiation. Clear plastics

actually heat the soil by transmitting light to the soil surface, rather than conducting heat

like dark plastics (Ham and Kluitenberg, 1994). Consequently, laying clear mulch

loosely across the soil creates an insulating air gap between the mulch and soil that

results in higher daytime temperatures under clear plastic than black plastic mulch

(Liakatas et al., 1986). If clear plastic is laid tightly across the bed its effects will be

minimized, and in this situation black plastic laid tightly across the bed would be more

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effective at heating the soil (Liakatas et al., 1986). Research with clear plastic surface

mulch in combination with supported row covers, has shown that clear plastic mulch is

more effective than black plastic in increasing early yield and total yield of spring

transplanted tomatoes (Ricketson and Thorpe, 1983). In controlled environments plant

root growth increases with increased temperature from a minimum to an optimum

temperature (Diaz-Perez and Batal, 2002) and increases past optimum temperatures are

accompanied by decreased root and shoot growth (Miller, 1986). Although no data are

available for optimum root zone temperature for field tomatoes (Diaz-Perez and Batal,

2002), research has shown that nutrient uptake from nutrient solutions are optimal at

25°C (Tindall et al., 1990). Research using black mulch for production of field tomatoes

has shown temperatures that steadily hovered 10-25 degrees above optimum temperature

throughout the season, and in these conditions straw mulch actually outperforms black

plastic (Tindall et al., 1991). In an effort to avoid the soil warming effects associated

with dark or clear plastics some growers will use white plastic as an alternative.

White mulch absorbs 51% of short-wave radiation, reflects 48% into the

atmosphere, and transmits only 1% of it to the soil (Tarara, 2000). This low rate of

radiation absorption (clay loam soils have an absorption rate of 70-86% depending on

moisture levels (Tarara, 2000)), and high rate of reflection leads to soil temperatures that

are at or below temperatures found on bare ground (Ham et al., 1993, Decoteau et al.,

1989). Although, increased foliage found over white plastic does not necessarily lead to

higher photosynthate produced (Decoteau et al., 1989).

Weed control is another important benefit of using mulch. In open- field tomato

production, a “critical weed free period” of 28-55 days exists, during which time a single

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thorough hand hoeing will prevent yield loss (Weaver and Tan, 1983). Weeds growing

before this timeframe will not compete significantly with the crop, whereas weeds

growing beyond this point will reduce yields primarily by shading the crop (Jensen et al.,

1989). Black mulch effectively stops weed growth by intercepting nearly all-incoming

radiation and, in combination with its soil warming effects, promotes early season weed

growth. Early season weed growth is confined and suppressed by clear plastic mulch as

the season progresses, making removal of the plastic and cultivation unnecessary

(Ricketson and Thorpe, 1983). Because weeds growing beneath clear plastic will push

up and against the mulch, care must be taken to firmly secure down the mulches edges to

prevent weeds from growing out from under the plastic and interfering with crop growth.

Floating Row Covers

Spun bonded fabric row covers, also known as floating row covers were first used

in the southern United States as tobacco seedbed covers (Wells and Loy, 1985). Small

diameter continuous filaments of polyester or polypropylene are spun in a web form onto

a collection belt. Next, the fibers are bonded with heat and pressure into a thin sheet of

flexible and porous fabric (Vaughn, 1992). Fabric row covers are lightweight (10-

50g/m²), and can be placed directly over crops without the use of hoops for support

(Wells and Loy, 1985). Row covers modify a plant’s growing environment in regard to

light, soil and air temperatures, humidity, and air movement (Wells and Loy, 1985).

Floating row covers are applied loosely over plants and secured at the edges. As the

plants grow they push against and lift the row cover, which necessitates their removal on

tall- growing crops such as tomatoes.

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Time between flowering and fruit development is much shorter at high rather than

moderate temperatures (Adballa and Verkerk, 1968). Wells and Loy (1985) showed that

temperatures under row cover can be several degrees warmer than ambient ones, and

research has also shown that temperatures under row covers can reach levels that may

cause abortion of flowers and unripe fruit (Wolfe et al., 1989; Wells and Loy, 1985).

Early yields on spring plantings will be reduced if row covers are not removed while

tomatoes are flowering (Rubeiz, I.G. and Freiwat, M.M. 1995; Peterson, R.H. and Taber,

J.G., 1991). In addition to regulating temperatures around the plant, row covers also

moderate low temperature extremes in the soil (Wells and Loy, 1993). Wells and Loy

(1993) report that seedlings of fall seeded lettuce in uncovered plots were pushed from

the soil with alternating freezing and thawing, while covered seedlings were not affected

by the weather fluctuations. The heat trapping effect of row covers is more pronounced

on fall crops rather than spring crops due to the large amount of heat stored in the soil

following the summer (Wells and Loy, 1993).

Drip Irrigation

Various reports have shown that vegetable yields can be increased by the use of

drip irrigation (Doss et al., 1977; Gornat et al., 1973; Renquist et al., 1982; Shmueli, M.

and D. Goldberg, 1971; Williams, J.W. and Sistrunk, W.A. 1979). The increased yield

when using drip irrigation has been attributed to better water utilization (Manfrinato,

1974), higher oxygen concentration in the root zone (Gornat et al., 1973; Inden, 1956),

and increased vegetative growth (Doss, 1977; Renquist, 19825), which resulted in more

flower clusters and increased fruit number (Renquist, 1982). Seventy-four to seventy five

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percent of the roots of shallow rooted vegetables have been found in the upper 10 to

15cm of the soil during experiments conducted on sandy soils using drip irrigation and

mulch (Bruce et al., 1980; Bruce et al., 1985; Singh et al., 1989). Although, in heavier

soils a higher percentage of roots will grow more deeply because of a greater water

holding capacity of the subsoil (Tindall, 1991). Therefore, in sandy soils, plants are at

greater risk of drought stress due to their lack of deep roots, and care should be taken to

apply water before the upper 10 to 15cm of soil is allowed to become dry.

Shrivastave et al. (1994) showed that using drip irrigation with plastic or organic

mulch increased tomato yields with less water applied, when compared to drip irrigation

with no mulch. Bhell (1988) found that early yields of tomatoes could be increased by

80% with the use of trickle irrigation and plastic mulch, over no irrigation and no mulch

treatments. These results were most likely due to a greater amount of weed pressure in

the non-mulched treatments, which highlights the importance of utilizing all of the

various components of a plasticulture system.

High Tunnels

High tunnels are unheated plant forcing structures covered with clear plastic and

made of metal bows connected to pipes that are driven into the ground and come in

various shapes. The end-walls are enclosed, and can be equipped with doors wide

enough to allow for entry of small equipment. High tunnels have no electric or gas

hookups and therefore have no supplementary heat or ventilation. A water line for drip

irrigation is the only connection needed for crop production in high tunnels. Although

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high tunnels have not been used extensively in the United States, they have, and are,

being used extensively in Southern Europe, the Middle-East, and Asia (Wells, 1991).

High tunnels must be manually ventilated during cool and sunny weather to

remove excess heat and humidity (Wells and Loy, 1993). Ventilation is facilitated by the

use of a three to five foot high role-up side-wall that extends the length of the structure on

both sides, allowing for cross ventilation (Wells and Loy 1993). The width of a high

tunnel cannot exceed twenty feet without suffering from inadequate ventilation (Wells

and Loy, 1993). Excessive humidity caused by less -than -optimal ventilation within

high tunnels is a factor that can negatively impact plant growth (Castilla, 1992). When

humidity is too high, water will condense in droplets on the inner surface of the tunnels

plastic covering. Condensation on the plastic covering has a negative effect on the

transmission of solar radiation if the droplets persist during daylight hours (Jaffrin et al.,

1990). Relative humidity levels above 90% can also cause developmental disorders

related to localized calcium deficiency, promote outbreak of fungal diseases, and

decrease flower pollination (Cockshull, 1988).

In Connecticut, tomatoes transplanted into tunnels on May 1 ripened three weeks

earlier than tomatoes planted into the field on the same date (Gent, 1991). Gent (1991)

reported that tomatoes transplanted into high tunnels on April 3, ripened 13 days earlier

than plants transplanted into tunnels on April 17. April 13 transplants yielded less than

six pounds of fruit per plant after seven weeks of harvest, compared to nine pounds of

fruit per plant for April 17 plantings. In this study, Gent also found that ventilation at

30°C within the tunnels was optimum during spring production. As a general rule for

spring tomato production, tunnels should be vented on sunny days when the outside

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temperature reaches 10°C (Gent, 1991). Conversely, for fall production Gent found that

reducing ventilation to achieve warm days reduced marketable percentage and size of

fruit, and increased disease levels. Ventilation for fall production should take place when

the inside temperature reaches 14°C to achieve the highest yield, fruit size, and fruit

quality (Gent, 1991). Each two week delay in planting after July 15 delayed ripening by

one month and reduced yields (Gent, 1991). However, the July 15 planting ripened

throughout September, which was in direct competition with field production. Therefore,

a late July planting in high tunnels may be the best compromise between yields, and

timing, to come into the market when field production has ceased (Gent, 1991).

Economics of High Tunnel Production

Overall yields for a single tomato crop grown within high tunnels are reported to

be just over two pounds per square foot (Wells, 1999; Upson, 2002). Both of these

researchers allocated about 110 hours of labor annually per high tunnel. When all costs

of building and operating a high tunnel are calculated, with depreciation of the structure

figured over a ten year period and tomato sales calculated at $1.50 a pound, Wells (1999),

and Upson (2002) both found that a profit could be realized from the first tomato crop

produced within a high tunnel.

The main benefit of the high tunnel is the premium price received from the early

yields between the middle of June and mid-July (Gent, 1991). In Connecticut, Gent

(1991) reported harvests slightly less than one pound of fruit per square foot from mid-

June through mid-July. While these yields may sound low, it is important to remember

that these tomatoes are available when prices are three times that of tomatoes sold after

field tomatoes come onto the market. A fall crop of tomatoes planted on July 17 can

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yield just over one pound of fruit per square foot, with the harvest beginning in late

September, and extending into November (Gent, 1991). Therefore, it may be profitable

for growers to consider pulling plants in mid-July when field tomatoes are plentiful, and

planting a fall crop that will be marketed after field crops are killed by frost.

Cultivar Selection

Tomatoes are bred to grow in a variety of climates and growing conditions

(Kopsell, 2000). Some tomato cultivars will produce a crop in less than two months

while others take more than three months of hot weather to produce ripe fruit. Tomatoes

differ among cultivars in their response to different light and fertilizer levels (Conover,

1997). Significant differences among cultivars in number of flowers have been observed

when tomato plants were grown using fabric row covers (Peterson, 1991). Tomato

cultivars bred for outdoor production will typically have more leaf area than is desirable

for plants grown in high tunnels (Saglam, 2000). In a protected growing area such as a

high tunnel greater leaf area can promote an environment that is conducive to fungal

diseases within the plants foliage due to moisture retention and lack of air movement

(Saglam, 2000).

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Chapter 3

Effect of Mulch and Row Covers on Yield of Tomatoes in High Tunnels

Abstract

Row covers and plastic mulch are effective at enhancing early yield of warm

season vegetables (Wells and Loy, 1985; Bhella, 1988). Little is known however about

the effects of row cover and different colored plastic mulches on high tunnel grown

tomatoes in the Central Midwest. The objective of this research was to compare the

effects on tomatoes of black plastic mulch, clear plastic mulch, and no mulch, each with

and without row cover when used in high tunnels. Total marketable yield and yield of

US number1 fruit from clear plastic mulch without row cover was significantly greater

than yield from bare ground without row cover. Early marketable yield from clear plastic

mulch without row cover was significantly greater than yield from black plastic mulch

with row cover, and bare ground with and without row cover. In this study, clear plastic

mulch was the most effective mulch treatment at increasing plant growth. Row cover

provided frost protection early in the season, although it minimized the soil warming

ability of clear and black plastic mulch by filtering incoming solar radiation.

Introduction

E.M. Emmert (1956) found black polyethylene mulch to be the cheapest and most

efficient method used to mulch vegetables. Benefits of plastic mulch include: increased

and earlier harvests, greater marketable yields, better weed control and insect

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management, and more efficient use of irrigation water and fertigation nutrients (Lamont,

1993). Major advances in plastics have taken place since E.M. Emmert’s work in the

early 50’s. Today growers can choose from a variety of mulches, each of which has

specific applications.

To extend the growing season of a certain crop, it is necessary to grow the crop in

sub-optimal conditions such as low temperature. Cool soil temperatures can have a

number of adverse effects on plant root growth such as slower cell division and cell

maturation rates, reduced water uptake, and reduced nutrient uptake (Nielsen, 1974).

Black and clear mulches have shown the greatest soil warming potential among the

various mulch colors (Ham et al., 1993). However, black and clear mulches heat the soil

in different ways, and the manner in which the mulch is applied to the soil is directly

related to its effectiveness.

Black mulch reflects less short-wave radiation (10%), and absorbs more radiation

(90%) than any other colored mulch (Teasdale, 1995). Dark colored mulches (black or

red) typically have higher surface temperatures than clear or white mulch (Decoteau et

al., 1989). The heat absorbed by dark colored mulches is conducted to the soil surface,

which raises the soil temperature (Tarara, 2000). Therefore, it is very important to apply

dark plastics tightly over the bed to maintain good soil -to- mulch contact. An air gap

between the mulch and the soil creates a greater distance for the heat to travel before

entering the soil and, consequently, much of the heat created at the mulch surface is lost

to the atmosphere (Tarara, 2000).

Clear mulch absorbs only 5% of short-wave radiation, reflects only 11%, but transmits

84% of short-wave radiation (Tarara, 2000). Clear mulch surface temperatures do not

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reach the levels found on black plastic due to their low absorption rates of short-wave

radiation. Clear plastics actually heat the soil by transmitting light to the soil surface,

rather than conducting heat like dark plastics (Ham and Kluitenberg, 1994).

Consequently, laying clear mulch loosely across the soil creates an insulating air gap

between the mulch and soil that results in higher daytime temperatures under clear plastic

than black plastic mulch (Liakatas et al., 1986; Ham et al., 1993). If clear plastic is laid

tightly across the bed, its effects will be minimized and, in this situation, black plastic

laid tightly across the bed would be more effective at heating the soil (Liakatas et al,

1986). Research with clear plastic surface mulch in combination with supported row

covers, has shown that clear plastic mulch is more effective than black plastic in

increasing early yield and total yield of spring transplanted tomatoes (Ricketson and

Thorpe, 1983).

Weed control is another important benefit of using mulch. In open field tomato

production, a “critical weed free period” of 28-55 days exists, during which time a single

thorough hand hoeing will prevent yield loss (Weaver and Tan, 1983). Weeds growing

before this timeframe will not compete significantly with the crop, whereas weeds

growing beyond this point will reduce yields primarily by shading the crop (Jensen et al.,

1989). Black mulch effectively stops weed growth by intercepting nearly all-incoming

solar radiation. Clear mulch on the other hand transmits a large portion of incoming

radiation, and in combination with its soil-warming effects promotes early season weed

growth. Early season weed growth is confined and suppressed by clear plastic mulch as

the season progresses, making removal of the plastic and cultivation unnecessary

(Ricketson and Thorpe, 1983). Because weeds growing beneath clear plastic will push up

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and against the mulch, care must be taken to firmly secure the mulches edges to prevent

weeds from growing out from under the plastic and interfering with crop growth.

Spunbonded fabric row covers, also known as floating row covers, were first used in the

southern United States as tobacco seedbed covers (Wells and Loy, 1985). Small-

diameter continuous filaments of polyester or polypropylene are spun in a web form onto

a collection belt. Next, the fibers are bonded with heat and pressure into a thin sheet of

flexible and porous fabric (Vaughn, 1992). Fabric row covers are lightweight (10-

50g/m²), and can be placed directly over crops without the use of hoops for support

(Wells and Loy,1985). Row covers modify a plant’s growing environment with regard to

light, soil and air temperatures, humidity, and air movement (Wells and Loy, 1985).

Floating row covers are applied loosely over plants and secured at the edges. As the

plants grow they push against and lift the row cover, which necessitates their removal on

tall growing crops such as tomatoes.

Time between flowering and fruit development is much shorter at warmer rather

than moderate temperatures (Abdalla and Verkerk, 1968). Wells and Loy (1985) showed

that temperatures under row cover can be several degrees warmer than ambient, and

research has also shown that temperatures under row covers can reach levels that may

cause flower and unripe fruit abortion (Wolfe et al., 1989; Wells and Loy, 1985). Early

yields on spring plantings will be reduced if row covers are not removed while tomatoes

are flowering (Rubeiz, I.G. and Freiwat, M.M.1995; Peterson, R.H. and Taber, H.G.,

1991). In addition to regulating temperatures around the plant, row covers also moderate

low temperature extremes in the soil (Wells and Loy,1993). Wells and Loy (1993) report

that seedlings of fall - seeded lettuce in uncovered plots were pushed from the soil with

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alternating freezing and thawing, while covered seedlings were not affected by the

weather fluctuations. The heat trapping effect of row covers is more pronounced on fall

crops rather than spring crops due to the large amount of heat stored in the soil following

the summer (Wells and Loy, 1993). The objective of this research was to compare the

effects on tomatoes of black plastic mulch, clear plastic mulch, and no mulch, each with

and without row cover when used in high tunnels.

Materials and Methods

Four high tunnels (HT) were constructed in June, 2001 at the University of

Missouri Bradford Research and Education Center located near Columbia, Missouri (Lat.

38N, Long. 92W). The experiments were carried out during fall of 2001, and the spring

and fall of 2002. The soil, a fine Mexico silt loam, montmorillonitic, mesic Mollic

Endoaqualf, was tilled, graded, and leveled prior to construction. Soil samples were

taken prior to planting and analyzed by the University of Missouri soil-testing laboratory.

Soil pH was 6.0, with 1.9% organic matter (see Appendix I). Each HT was 6mx11mx3m,

giving 66 m² of total planting space (Stuppy Greenhouse Mfg., Inc., Kansas City, MO).

Bows were spaced 1.2 meters apart, and one purlin was used for each tunnel. For

ventilation, a 1m high roll-up sidewall was used. The roll-up sidewall extended the

length of both sides of the high tunnels and was rolled up manually. Tunnels were built

with the long axis oriented east-west to intercept the areas prevailing south by southwest

wind. Each tunnel was covered with a single layer of clear 6 mil plastic (K-50, Klerk’s

Plastic Products Manufacturing Inc., Richburg, SC). Plots were irrigated with 2.54 cm of

water weekly through 8mm t- tape with 12” emitter spacing and a flow rate of 0.450 gpm

(TSX-508, T-Systems International, San Diego, CA). Row cover treatments consisted of

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covering with a double layer of Agribon AG-19 row cover, which weighs 19g/m²

(Agribon, Mooresville, NC). A granular 13N-13P-13K fertilizer was applied pre - plant

to all plots at the rate of 56 kg nitrogen per hectare (5.6 g/m²). Calcium nitrate (CaNO3),

with an analysis of 15% N and 19% Ca, was applied weekly beginning four weeks after

planting through the drip irrigation at a rate of 10 kg/ha (1 g/m²). Five cm (606) plastic

cell-packs (164 cm³ per cell) with Pro-Mix BX® (Premier Peat Co. (75-85% peat by

volume, perlite, vermiculite, macro- and micro - nutrients and wetting agent)) were used

to start seed in the University of Missouri Horticultural Greenhouses. Seedlings were

grown at 22ºC daytime temperature and 20ºC night temperature for eight weeks prior to

transplanting.

Tomato plants in all treatments were spaced 0.6 m in rows with 0.9 m between

rows. Tomatoes were trellised using the string weave method, with two tomato plants

between each stake and approximately 4 strings to support the plants.

Tomato plants ( Lycopersicon esculentum Mill.) were grown to evaluate their early

season yield characteristics when grown using different mulch types with and without

row cover. Six treatments were evaluated: clear plastic mulch without row cover, clear

plastic mulch with row cover, black plastic mulch without row cover, black plastic mulch

with row cover, bare ground without row cover, bare ground with row cover (Table 1).

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Table 1. Mulch and Row Cover Treatments

Mulch Type With Row cover Bare Ground yes

Bare Ground

yesBlack Plastic

Black Plastic

Clear Plastic

Clear Plastic

yes

There were four replications for each treatment arranged in a completely

randomized block design. A one- way analysis of variance (ANOVA) was computed for

all data and differences were determined using Fisher’s Least Significant Difference

(LSD). Plants were set into rows of 16 plants, with each row being split into a row cover,

and a no row cover treatment. Each treatment contained 8 plants. Plants in the row cover

treatments were covered continuously, with a double layer, until first flowers appeared.

During and after flowering, row covers were removed when daytime temperatures

exceeded 15ºC, and replaced when night temperatures dropped below 13ºC. Pollination

was accomplished by natural insect populations and air movement. Tomato transplants

were planted in the tunnels on March 21, 2002.

Fruit harvest on spring tomatoes began on June 12, 2002, and continued through

July 18, 2002. Yields were recorded on a per - plant basis, and fruit was graded

according to USDA grade standards (USDA, 1966).

Fall plantings were made on August 10, 2001, and August 1, 2002. Treatments

were made up of two rows (16 plants per row) of plants in each of four high tunnels. One

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row was covered with row cover, and the other was not. Tomato fruit did not have

enough time to ripen in both season and a harvest was never accomplished. On

November 3 of 2001, and 2002 necrotic tissue due to cold damage was removed from

plants grown with and without row cover. Necrotic tissue that was damaged immediately

following freezing temperatures were considered to be cold damaged. Weights of

necrotic tissue were recorded separately for each treatment.

Results

Total marketable yield and yield of US number1 fruit (USDA, 1966) from clear

plastic mulch without row cover treatments was significantly greater than yield from bare

ground without row cover (Table 2). Yield of grade 2 fruit from bare ground with row

cover was significantly greater than that of clear plastic mulch with row cover. No

significant difference existed between any other treatments for full season yield. Both

mulch types (clear and black) use solar energy to heat the soil. Black mulch heats the soil

by conduction of heat from the plastic to the soil. Clear mulch heats the soil through

transmission of solar radiation through the plastic and onto the soil surface. The soil

warming effects of mulches are important early in the season because cool soil

temperatures have a number of adverse effects on plant root growth such as reduced

nutrient uptake (Nielsen, 1974). Based on light intensity readings taken during this

project, a double layer of AG 19 row cover blocked an average of 40% of incoming solar

radiation from the plants and the soil surface. Mulch under row cover was not able to

heat the soil as effectively as mulch without row cover because it did not receive as much

solar radiation. However, row covers retained heat, resulting in more vigorous plant

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growth early in the season. Filtration of solar radiation to the mulch surface and heat

retention by the row cover lead to similar yield from mulched treatments with and

without row cover.

Table 2. Total Yield of Mulch Treatments

Totalyield

USDA # 1fruit

USDA#2fruitTreatment

g/plant g/plant g/plantBare Ground

2953b¹ 2357b 710ab

Bare Ground row cover3777ab 2925ab 823a

Black Plastic3720ab 2925ab 710ab

Black Plastic row cover3720ab 2896ab 681ab

Clear Plastic4004a 3322a 624ab

Clear Plastic row cover 3663ab 3038ab 568b¹Means within the same column followed by the same letterare not significantly different at the 5% level based on LSD

Early marketable yield from clear plastic mulch without row cover was

significantly greater than yield from black plastic mulch with row cover, and bare ground

with and without row cover (Table 3). Early yield of grade 1 fruit from clear plastic was

significantly greater than all other treatments except clear plastic with row cover. Black

plastic mulch with row cover yielded no grade 2 fruit early in the season, and no

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significant difference existed for early yield of grade 2 fruit among all other treatments.

Greater early yield from clear plastic mulch treatments could be attributed to the fact that

clear plastic mulch heated the soil more than black plastic mulch or bare ground,

resulting in more favorable growing conditions early in the growing season.

Table 3. Early Yield of Mulch Treatment (Before July 4)

Totalyield USDA #1fruit USDA #2fruitTreatmentg/plant g/plant g/plant

Bare Ground 1051b¹ 795b 454a

Bare Ground 1079b 852b 369arow cover

Black Plastic 1164ab 880b 426a

Black Plastic1079b 880b 0b

row cover

Clear Plastic 1704a 1363a 369a

Clear Plastic1221ab 1079ab 284a

row cover

¹Means within the same column followed by the sameletter are not si nificantl different at the 5% level based

Row covers significantly reduced the amount of necrotic foliage due to cold

exposure on plants in 2001, and eliminated damage in 2002 (Table 4). Damage under

row cover in 2001 occurred only at points in which the plants contacted the row cover.

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Table 4. Necrotic Tissue Due to Cold Dama e

Necrotic Tissue Necrotic TissueTreatment

Fall 2001/g Fall 2002/g

Row cover 1925b¹ 0b

No Row Cover 5955a 2131a

¹Means within the same column followed by the sameletter are not significantly different at the 5% level basedon LSD

Discussion

Row covers did not significantly increase total, or US number 1 yield of high

tunnel tomatoes. Row covers did provide added frost protection in addition to the

protection afforded by a high tunnel. Row covers, however, required extra capital for

their purchase, and extra labor to put them on and remove them when plants were

flowering and when daytime temperatures were high. When using black or clear plastic

mulch, row covers were only useful for frost protection during times when the

temperature within the high tunnel dropped below freezing. When plants were small, it

was advantageous to support row covers over the plants to avoid direct contact of the

plant and row cover. Tissue damage on plants at the point of contact with the row covers

was designated as frost damage due to the absence of disease or insects that may have

caused the damage, and appearance of the damaged tissue immediately following a frost.

Using high tunnels and row covers for frost protection on full-grown plants, damage was

localized to the points on the plants that were in direct contact with the row cover.

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Early yield from bare ground with row cover treatments did not differ

significantly from any of the mulch treatments except clear plastic. Treatments grown

without mulch required one thorough hand cultivation during the season. Hand

cultivation was labor intensive, but was the only feasible way to eliminate weeds in the

tightly spaced high tunnel. Clear and black plastic mulches were effective enough at

suppressing weeds that no cultivation was necessary. There was, however, capital

required to purchase plastic mulch, and labor involved with applying plastic mulch. The

total cost of purchasing and applying the mulch was comparable to the cost of labor

involved with cultivating weeds by hand. Therefore, growing tomatoes on bare ground in

high tunnels with the use of floating row cover is more economical than using black

plastic mulch.

Clear plastic mulch significantly increases early yield of grade 1 fruit over all

other treatments. This increase in production occurs at a time when tomato prices are

high because field tomatoes have not yet come onto the market.

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Chapter 4

Evaluation of Yield Potential in High Tunnels for Eight Tomato

Cultivars

Abstract

Many popular tomato cultivars are used for field production in Missouri.

Growing conditions within a high tunnel can be quite different from growing conditions

typically encountered in outdoor production. Tomatoes grown in a high tunnel are

exposed to high relative humidity, lower light, and more extreme temperature

fluctuations than field- grown tomatoes. The effect of environmental factors within high

tunnels on yield of popular field- grown tomato cultivars is unknown. The objective of

this research was to determine yield characteristics throughout the growing season for

several popular tomato cultivars commonly grown in Missouri. Total early yields from

BHN 543, and Merced were significantly greater than all other cultivars (Table 2). Early

yield of number one fruit from BHN 543 was significantly greater than most other

cultivars, and was equal to that of Merced, and Florida 91. Full season yield of grade 1

and 2 fruit combined was significantly greater for Merced than any other cultivar (Table

2). Total yield of grade 1 fruit was greater for Merced than all other cultivars except

Florida 47, and Florida 91.

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Introduction

High tunnels are unheated plant forcing structures covered with clear

plastic and made of metal bows connected to pipes that are driven into the ground and

come in various shapes. The end-walls are enclosed, and can be equipped with doors

wide enough to allow for entry of small equipment. High tunnels have no electric or gas

hookups and therefore have no supplementary heat or ventilation. A water line for drip

irrigation is the only connection needed for crop production in high tunnels. Although

high tunnels have not been used extensively in the United States, they have, and are,

being used extensively in Southern Europe, the Middle-East, and Asia (Wells, 1991).

High tunnels must be manually ventilated during cool and sunny weather to

remove excess heat and humidity (Wells and Loy, 1993). Ventilation is facilitated by the

use of a three to five foot high role-up side-wall that extends the length of the structure on

both sides, allowing for cross ventilation (Wells and Loy, 1993). The width of a high

tunnel cannot exceed twenty feet without suffering from inadequate ventilation (Wells

and Loy, 1993). Excessive humidity caused by less -than -optimal ventilation within

high tunnels is a factor that can negatively impact plant growth (Castilla, 1992). When

humidity is too high, water will condense in droplets on the inner surface of the tunnel’s

plastic covering. Condensation on the plastic covering has a negative effect on the

transmission of solar radiation if the droplets persist during daylight hours (Jaffrin et al.,

1990). Relative humidity levels above 90% can also cause developmental disorders

related to localized calcium deficiency, promote outbreak of fungal diseases, and

decrease flower pollination (Cockshull, 1988).

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In Connecticut, tomatoes transplanted into tunnels on May 1 ripened three weeks

earlier than tomatoes planted into the field on the same date (Gent, 1991). Gent (1991)

reported that tomatoes transplanted into high tunnels on April 3, ripened 13 days earlier

than plants transplanted into tunnels on April 17. April 13 transplants yielded less than

six pounds of fruit per plant after seven weeks of harvest, compared to nine pounds of

fruit per plant for April 17 plantings. In this study, Gent also found that ventilation at

30°C within the tunnels was optimum during spring production. As a general rule for

spring tomato production, tunnels should be vented on sunny days when the outside

temperature reaches 10°C (Gent, 1991). Conversely, for fall production Gent found that

reducing ventilation to achieve warm days reduced marketable percentage and size of

fruit, and increased disease levels. Ventilation for fall production should take place when

the inside temperature reaches 14°C to achieve the highest yield, fruit size, and fruit

quality (Gent, 1991). Each two week delay in planting after July 15 delayed ripening by

one month and reduced yields (Gent, 1991). However, the July 15 planting ripened

throughout September, which was in direct competition with field production. Therefore,

a late July planting in high tunnels may be the best compromise between yields and

timing, to come into the market when field production has ceased (Gent, 1991). The

objective of this research was to determine yield characteristics throughout the growing

season for several popular tomato cultivars commonly grown in Missouri.

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Materials and Methods

Four high tunnels (HT) were constructed in June, 2001 at the University of

Missouri Bradford Research and Education Center located near Columbia, Missouri (Lat.

38N, Long. 92W). The experiments were carried out during fall of 2001, and the spring

and fall of 2002. The soil, a fine Mexico silt loam, montmorillonitic, mesic Mollic

Endoaqualf, was tilled, graded, and leveled prior to construction. Soil samples were

taken prior to planting and analyzed by the University of Missouri soil-testing laboratory.

Soil pH was 6.0, with 1.9% organic matter (see Appendix I). Each HT was 6mx11mx3m,

giving 66 m² of total planting space (Stuppy Greenhouse Mfg., Inc., Kansas City, MO).

Bows were spaced 1.2 meters apart, and one purlin was used for each tunnel. For

ventilation, a 1m high roll-up sidewall was used. The roll-up sidewall extended the

length of both sides of the high tunnels and was rolled up manually. Tunnels were built

with the long axis oriented east-west to intercept the areas prevailing south by southwest

wind. Each tunnel was covered with a single layer of clear 6 mil plastic (K-50, Klerk’s

Plastic Products Manufacturing Inc., Richburg, SC). Plots were irrigated with 2.54 cm of

water weekly through 8mm t- tape with 12” emitter spacing and a flow rate of 0.450 gpm

(TSX-508, T-Systems International, San Diego, CA). Row cover treatments were

covered with a double layer of Agribon AG-19 row cover, which weighs 19g/m²

(Agribon, Mooresville, NC). A granular 13N-13P-13K fertilizer was applied pre plant to

all plots at the rate of 56 kg nitrogen per hectare (5.6 g/m²). Calcium nitrate (CaNO3)

was applied weekly through the drip irrigation at a rate of 10 kg/ha (1 g/m²).

Five cm (606) plastic cell-packs (164 cm³ per cell) with Pro-Mix BX® (Premier

Peat Co., Quebec) 75-85% peat by volume, perlite, vermiculite, macro and micro

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nutrients and wetting agent)) were used to start seed in the University of Missouri

Horticultural Greenhouses. Seedlings were grown at 22ºC daytime temperature and 20ºC

night temperature for eight weeks prior to transplanting.

Tomato plants in all treatments were spaced 0.6 m in rows and 0.9 m between

rows. Tomatoes were trellised using the string weave method, with two tomato plants

between each stake.

Tomato ( Lycopersicon esculentum Mill) cultivars that are commonly grown as

field crops were grown to evaluate their performance as an early season crop in high

tunnels. Tomato cultivars included: Florida 47, Florida 91, Floralina, Merced, Carolina

Gold, Brandywine, BHN 543, and Mt. Fresh.

Florida 47 is a vigorous, determinate tomato that ripens mid-season with very

large fruit (Sieger, 2000). Florida 91 is medium-tall determinate, heat tolerant, early to

mid-season cultivar with large fruit (Sieger, 2000). Floralina is a medium-tall

determinate cultivar that bears large fruit that ripens early to mid-season (Tomato

Growers Supply Co., Fort Myers). Merced is an early-ripening, determinate cultivar with

large fruit (Grant, 1997). Carolina Gold is a tall determinate cultivar that ripens mid-

season with large, yellow- colored fruit (Syngenta Seeds Inc., Basal). Brandywine is an

heirloom cultivar with an indeterminate growth habit and large fruit that ripen late in the

season (Tomato growers supply Co., Fort Myers). BHN 543 is a medium-tall,

determinate cultivar with large fruit ripening early to mid-season (Sieger, 2000). Mt.

Fresh is a tall, determinate cultivar with large fruit that ripen mid-season (Sieger, 2000).

There were four replications for each cultivar arranged in a completely

randomized block design. A one- way analysis of variance (ANOVA) was computed for

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all data and differences were determined using Fisher’s Least Significant Difference

(LSD). Plants were set into rows of sixteen plants, with four plots per row. Each plot

contained four plants. Plants were grown using black plastic mulch, and were covered

with row cover continuously until the first flowers appeared. During flowering, row

covers were removed in the morning and replaced in the afternoon. When the weather

began warming, row covers were only used on evenings when the temperature dropped

below 10°C. Pollination was accomplished by natural insect populations and air

movement. Tomato transplants were planted in the high tunnels on March 24, 2002.

Fruit harvest began on June 12, 2002, and continued through July 18, 2002.

Yields were recorded on a per plant basis, and fruit was graded according to USDA grade

standards (USDA, 1966).

Results

Total early yields from BHN 543, and Merced were significantly greater than all

other cultivars (Table 5). No significant difference existed for early yield of any other

cultivars. Early yield of number one fruit from BHN 543 was significantly greater than

most other cultivars, and was equal to that of Merced, and Florida 91. Twenty Two

percent of the early fruit collected from the cultivar BHN 543 were culls (Table 5), most

of which were attributed to rabbit damage. Rabbits were attracted to the high tunnels due

to their warm conditions, food source and thick cover afforded by the tomato plants.

BHN 543 set fruit very low to the ground, which made it easy for the rabbits to get to the

fruit. The heirloom tomato cultivar Brandywine produced significantly less early total

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and grade 1 (USDA, 1966) fruit per plant than Merced or BHN 543. Brandywine yielded

an equal amount of early grade 2 fruit as Merced and BHN 543, even though it produced

significantly less marketable fruit than either variety. Forty- one percent of the fruit

picked from Brandywine before July 4 were culls. Culls from Brandywine were mostly

attributed to fruit cracking and surface blemishes (Table 6).

Table 5. Early Yield for Cultivar Trial (Before July 4)

USDA #1fruit

USDA #2fruit

Total yieldg/plant

%Culls

Cultivarg/plant g/plant

540 abBHN 543 2045 a¹ 1477 a 22

710 aMerced 2016 a 1420 ab 13

341 bCarolina Gold 1278 b 1022 bdc 16

Florida 91 1278 b 1164 bac 284 b 19

483 abFlorida 47 1221 b 880 dc 17

625 aBrandywine 1193 b 795 dc 41

625 aFloralina 1164 b 682 d 23

Mt. Fresh 1022 b 852 dc 284 b 5

¹Means within the same column followed by the same letter are notsignificantly different at the 5% level based on LSD.

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Table 6. Percent Culls Due to Applicable Reason

Cultivar % BER¹ % Rabbit % Fruit Worm % Crack % SurfaceBlemish

BHN 543 0 70 24 0 2Brandywine 0 2 11 33 38Carolina Gold 8 12 56 0 24Floralina 23 18 23 0 11Florida 47 5 40 23 3 0Florida 91 9 27 32 0 32Merced 22 14 14 28 14Mt. Fresh 23 7 23 38 0

¹Blossom End Rot

Full season yield of grade 1 and 2 fruit combined was significantly greater for

Merced than any other cultivar (Table 7). Total yield of grade 1 fruit was greater for

Merced than all other cultivars except Florida 47, and Florida 91. Florida 47, and Florida

91 were bred to perform well in hot weather, although their yield throughout the season

was not significantly greater than any variety other than Brandywine. Merced also

produced a significantly greater number of grade 2 fruits than any other cultivar, which

could be attributed to the fact that overall yields for Merced were also significantly

greater than most other cultivars.

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Discussion

Central Missouri experienced an unusually wet spring in 2002. Because of the

wet weather, field tomatoes were late coming onto the market and farmer’s market

tomato prices stayed over $2.00 per pound through the middle of July. While wet spots

did exist near the edges of the high tunnels, conditions in the high tunnels were much

drier and therefore more conducive to plant growth. Protecting the plants from rain with

the high tunnels allowed for early harvest of high quality fruit even though field

conditions were poor.

Cultivar

Total Yield

g/plant

USDA #1

fruitg/plant

USDA #2

fruitg/plant

%

Culls

Merced 5992 a¹ 4374 a 1562 a 14

Floralina 4516 b 3181 b 1051 b 15

Florida 47 4316 b 3380 ab 852 bc 18

Mt. Fresh 3976 b 3096 bc 710 bc 9

Florida 91 3976 b 3408 ab 540 c 14

BHN 543 4004 b 3096 bc 852 bc 19

Carolina Gold 3976 b 3209 b 653 bc 16

Brandywine 3266 c 2130 c 1051 b 30

Table 7. Yield Data for Cultivar Trial

¹Means within the same column followed by the same letterare not significantly different at the 5% level based on LSD.

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Merced and BHN 543 are both excellent choices for early season tomato

production in high tunnels. Merced also carried a large fruit load throughout the season.

BHN 543 would be a good choice for growers who wish to produce an early crop of

tomatoes that will be pulled out early in the summer and followed by another crop.

During harvest it was noted by a three person panel of judges that fruit from BHN 543

had better flavor than Merced. Early in the season flavor would not limit sales of Merced

because demand for tomatoes at that time exceeds supply, although later in the season

retail consumers may choose other more flavorful cultivars as they become available.

Results from this research indicate that controlling rabbit populations in and

around high tunnels would have lead to a higher percentage of marketable fruit. The

number of culls attributed to fruit worm damage could have been reduced by scheduled

applications of BT ( Bacillus thuringiensis).

Carolina Gold had good yield, excellent flavor, and is recommended for

producers of yellow tomatoes. Yield from the heirloom tomato cultivar Brandywine did

not compare to newer hybrid cultivars, although, Brandywine had extremely flavorful

fruit that is popular with many consumers. Brandywine would only be profitable to

produce if a market exists in which producers could charge a premium for the heirloom

tomato even though the fruit is not as blemish free as other cultivars. Mt. Fresh produced

very few culls and a low number of grade 2 fruit. Mt. Fresh was an extremely vigorous

growing and bushy plant. It was noted that the thick vegetative growth restricted airflow

within the plant and led to greater levels of powdery mildew on Mt. Fresh than on other

varieties. Therefore, a fungicide application could have led to lower fungal disease rates

on the Mt. Fresh cultivar.

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Chapter 5

SUMMARY AND CONCLUSIONS

Tomato plants ( Lycopersicon esculentum Mill) were grown to evaluate their early

season yield characteristics when grown using different mulch types with and without

row cover. Mulch treatments included plants grown on clear and black plastic mulch and

a control group of plants grown on bare ground. Half of the plants in each experimental

plot were covered with row cover and half were not. In a similar experiment, eight field

tomato cultivars were grown in high tunnels in order to evaluate their yield potential

throughout the growing season. Plants in the cultivar experiment were grown on black

plastic mulch and covered with row cover. Row covers did not significantly increase

total, or US number 1 yield of high tunnel tomatoes. When using black or clear plastic

mulch, row covers were only useful for frost protection during times when the

temperature within the high tunnel dropped below freezing. Early yield from bare ground

with row cover treatments did not differ significantly from any of the mulch treatments

except clear plastic. Clear plastic mulch significantly increases early yield of grade 1

fruit over all other treatments. This increase in production occurs at a time when tomato

prices are high because field tomatoes have not yet come onto the market.

Total early yields from BHN 543 and Merced were significantly greater than all

other cultivars. Twenty- Two percent of the early fruit collected from the cultivar BHN

543 were culls, most of which were attributed to rabbit damage. Controlling rabbit

populations in and around high tunnels could lead to a higher percentage of marketable

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fruit. Due to early fruit ripening characteristics, BHN 543 could fit into a double

cropping system for growers wanting to replant their high tunnels with a fall crop. Full

season yield of grade 1 and 2 fruit combined was significantly greater for Merced than

any other cultivar. The heirloom tomato cultivar Brandywine produced significantly less

early total and grade 1 fruit per plant than Merced or BHN 543.

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Chapter 6

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Appendix I: Soil Test Results

Soil Test Results Using Bray 1 Test

Sample

pH

O.M.

P

Ca

Mg

K

N.A.

Meq/100g %

Lbs/A

Lbs/A

Lbs/A

Lbs/A

High Tunnel 1

6.3

1

3.6

95

5849

523

198

High Tunnel 2 5.9 2.5 3.4 84 5581 530 178

High Tunnel 3 6.1 1.5 2.9 65 5846 549 169

High Tunnel 4 5.9 2.5 3 57 5739 611 194

Documents

Effects of Plastic Mulch, Row Cover & Cultivar Selection on Growth of Tomatoes in High Tunnels; Gardening Guidebook for Boone County, Missouri